JP2019082303A - Hot water supply system - Google Patents

Abstract

To provide a technology to advance boiling start time when hot water supply of a current day is expected to be started earlier than estimated hot water supply start time.SOLUTION: A hot water supply system includes a tank for storing water, a heat source machine for boiling the water in the tank, a hot water supply path for supplying the water from the tank to a bathtub, and a control device that can communicate with a cooking device. The control device estimates hot water supply start time of a current day and a dinner cooking start time based on the hot water supply start time and the dinner cooking start time of each day in a past predetermined period. The control device sets the boiling start time of the current day based on the estimated hot water supply start time of the current day, and executes boiling of the water in the tank by the heat source machine when the set boiling start time comes. The control device advances the set boiling start time when dinner cooking is started by a cooking unit on the current day before the estimated dinner cooking start time of the current day comes.SELECTED DRAWING: Figure 3

Description

  The technology disclosed herein relates to a hot water supply system.

  Patent Document 1 discloses a hot water supply system including a tank for storing water, a heat source machine for boiling the water of the tank, a hot water path for supplying water from the tank to the bathtub, and a control device capable of communicating with the cooking device. ing. The control device is configured to estimate the hot water start time of the current day based on the hot water start time which is the time when the water supply to the bathtub is started for each day in the past predetermined period . The control device sets the boiling start time of the day based on the estimated hot water start time of the day, and executes the boiling of the water of the tank by the heat source machine when the set boiling start time comes Is configured as.

JP, 2013-224762, A

  In the hot water supply system as described above, there is a risk that the high temperature water supplied from the tank to the bathtub may run short if the hot water heating on the day is started earlier than the estimated hot water heating start time.

  The present specification provides a technique for solving the above-mentioned problems. In the present specification, there is provided a technology capable of advancing the boiling start time when it is expected that the current day's hot water will start earlier than the estimated hot water start time.

  The hot water supply system disclosed in the present specification includes a tank for storing water, a heat source machine for boiling water in the tank, a hot water passage for supplying water from the tank to the bath, and a control device capable of communicating with the cooking device. There is. The control device sets a hot water start time, which is a time when supply of water to the bathtub is started, and a supper cooking start time, which is a time when dinner cooking is started by the cooking apparatus, for each day in a predetermined period in the past It is comprised so that the hot water start time of the day and the dinner cooking start time may be estimated based on. The control device sets the boiling start time of the day based on the estimated hot water start time of the day, and executes the boiling of the water of the tank by the heat source machine when the set boiling start time comes Is configured as. The control device is configured to advance the set boiling start time when the cooking of the dinner is started by the cooking device on the day before the estimated dinner cooking start time of the day comes.

  Generally, when the user returns home early, dinner and bathing are performed at an earlier time accordingly, and when the user returns home late, dinner and bathing are performed at a later time accordingly. Therefore, when the user comes home early, the dinner cooking start time and the hot water start time tend to be early, and when the user comes home late, the dinner cooking start time and the hot water start time tend to be delayed. . For this reason, when the time when the cooking of the supper was started by the cooking apparatus on the day is earlier than the supper cooking start time estimated from the past results, the user has returned home earlier, and the hot water bath of the day The start time of may also be earlier than the hot water start time estimated from past results. According to the above configuration, the boiling start time can be advanced when it is predicted that the hot water on the day will be started earlier than the estimated hot water start time.

  In the above-described hot water supply system, the control device does not change the set boiling start time when the cooking of the dinner is started by the cooking device on the day after the estimated dinner cooking start time of the day has come May be configured.

  If the time when the cooking of the dinner was started by the cooking device on the day is later than the dinner cooking start time estimated from the past results, it is considered that the user is coming home late. However, even when the user returns home late, the hot water start time may not change. In such a case, if the boiling start time is delayed, there is a risk that the hot water supplied from the tank to the bathtub will be insufficient when the hot water pouring on the day is started. According to the above configuration, it is possible to reliably store high-temperature water in the tank when hot water heating on the day is started.

  Another hot water supply system disclosed herein includes a tank for storing water, a heat source machine for boiling water in the tank, a hot water passage for supplying water from the tank to the bath, and a control device capable of communicating with the cooking apparatus. Have. The control device is configured to supply the water to the bathtub after the start of the supper cooking by the cooking apparatus and the hot water start time that is the time at which the supply of water to the bathtub was started for each day in the past predetermined period. It is comprised so that the hot water start time of the day and the dinner cooking and hot water baking time difference may be estimated based on the dinner cooking and hot water baking time difference which is a time difference until it starts. The control device sets the boiling start time of the day based on the estimated hot water start time of the day, and executes the boiling of the water of the tank by the heat source machine when the set boiling start time comes Is configured as. The control device is set when the time difference from the time when the cooking of the dinner was started by the cooking device on the day to the estimated start time of the hot water on the day is larger than the estimated dinner time on the current day It is configured to advance the boiling start time.

  When the time difference from the time when the cooking of the supper was started by the cooking device on the day to the hot water start time estimated from the past results is larger than the dinner cooking / hot water time difference estimated from the past results, Dinner preparation on the day has been performed from an early time, so the user may be returning home early. According to the above configuration, the boiling start time can be advanced when it is predicted that the hot water on the day will be started earlier than the estimated hot water start time.

  In the above-described hot water supply system, the control device determines the time difference from the time when the cooking of the dinner was started by the cooking device on the day to the estimated start time of the hot water on the day from the estimated dinner cooking / hot water time difference on the day When the temperature is too small, the set boiling start time may not be changed.

  If the time difference from the time when the cooking of the dinner was started by the cooking device on the day to the start time of the hot water bath estimated from the past results is smaller than the dinner cooking / hot water time lag estimated from the past results, the dinner on the day Cooking is done at a late time, so the user may be coming home late. However, even when the user returns home late, the hot water start time may not change. In such a case, if the boiling start time is delayed, there is a risk that the hot water supplied from the tank to the bathtub will be insufficient when the hot water pouring on the day is started. According to the above configuration, it is possible to reliably store high-temperature water in the tank when hot water heating on the day is started.

  In the above-described hot water supply system, the control device is configured to determine that the cooking is not the cooking of the dinner when the cooking is finished before the predetermined time has elapsed since the cooking was started by the cooking device. May be

  In the cooking apparatus, various kinds of cooking are performed in addition to cooking for dinner. Usually, dinner preparation is performed for a time longer than a predetermined time (for example, 10 minutes). According to said structure, it can be correctly discriminate | determined whether the cooking performed with the cooking apparatus is cooking of dinner.

  In the above-described hot water supply system, the control device may be configured to determine that the cooking is not the cooking of the dinner when the cooking is started by the cooking device before the predetermined time.

  In the cooking apparatus, in addition to dinner preparation, breakfast preparation and lunch preparation are performed. Usually, dinner preparation is performed after a predetermined time (for example, 14:00). According to said structure, it can be correctly discriminate | determined whether the cooking performed with the cooking apparatus is cooking of dinner.

  In the above-described hot water supply system, the control device may be configured to determine that cooking is not cooking for dinner when cooking is started by the cooking device after the start of supply of water to the bathtub .

  In order to accelerate the boiling time of the water in the tank before the hot water is poured to the bathtub, focusing on the time when the cooking of the dinner was started by the cooking device on the day, It is necessary to pay attention to the cooking of the supper which was carried out before the water bath. According to the above configuration, it is possible to accurately estimate the dinner cooking start time of the day and the dinner cooking / hot water baking time difference based on the past results.

  In the above-described hot water supply system, the control device may include a server-side control device and a client-side control device capable of communicating with the server-side control device.

  According to the above configuration, the process performed by the client-side control device can be simplified.

The figure which shows typically the structure of the hot-water supply systems 2 and 92 of Example 1, 2. FIG. The figure which shows typically the structure of the hot-water supply apparatus 4 of Example 1,2. The figure which shows typically the time slot | zone when cooking is performed in a general household, and the time slot | zone when hot-water supply is performed. The flowchart which shows the 1st heat pump operation | movement process which the control part 70 of Example 1, 2 performs. The flowchart which shows the 2nd heat pump operation | movement process which the control part 70 of Example 1, 2 performs. The flowchart which shows the hot-water-heating process which the control part 70 of Example 1, 2 performs.

Example 1
As shown in FIG. 1, the hot water supply system 2 according to the present embodiment includes a hot water supply device 4, a cooking device 100, a router 200, and a server device 300. The hot water supply device 4 and the cooking device 100 can communicate with each other. The water heating apparatus 4 can be connected to the Internet 250 via the router 200. The server device 300 is connected to the Internet 250. Therefore, the hot water supply apparatus 4 can communicate with the server device 300 via the router 200 and the Internet 250.

  As shown in FIG. 2, the hot water supply device 4 includes a tank 10, a tank water circulation passage 20, a tap water introduction passage 30, a supply passage 40, a heat pump 50, a combustion device 60, a control unit 70, and a remote control 80. Equipped with

The heat pump 50 is a heat source which heats the water in the tank water circulation passage 20 by absorbing heat from the outside air which is a natural environment. Although not shown, the heat pump 50 includes a refrigerant circulation path that circulates a refrigerant (such as substitute fluorocarbon or natural refrigerant such as R410A, propane, CO ₂ etc.), an evaporator that exchanges heat between the outside air and the refrigerant, and the refrigerant A compressor that compresses to a high temperature and high pressure, a condenser that performs heat exchange between water in the tank water circulation passage 20 and a high temperature and high pressure refrigerant, and decompresses the refrigerant after heat exchange to a low temperature and low pressure And an expansion valve.

  The tank 10 stores the hot water heated by the heat pump 50. The tank 10 is of a closed type and is covered on the outside by a heat insulating material. Water is stored in the tank 10 to full water. In the present embodiment, the capacity of the tank 10 is 100L. In the tank 10, thermistors 12, 14, 16, 17, 18 are attached at predetermined intervals in the height direction of the tank 10. Each thermistor 12, 14, 16, 17, 18 measures the temperature of the water at its mounting position. For example, the thermistors 12, 14, 16, 17, 18 respectively measure the temperature of water at positions 6L, 12L, 30L, 50L, 70L from the top of the tank 10.

  The tank water circulation passage 20 has an upstream end connected to the lower portion of the tank 10 and a downstream end connected to the upper portion of the tank 10. A circulation pump 22 is interposed in the tank water circulation passage 20. The circulation pump 22 pumps the water in the tank water circulation passage 20 from the upstream side to the downstream side. Further, the tank water circulation passage 20 passes through the condenser of the heat pump 50. Therefore, when the heat pump 50 is operated, the water in the tank water circulation passage 20 is heated by the condenser of the heat pump 50. Therefore, when the circulation pump 22 and the heat pump 50 are operated, the water in the lower part of the tank 10 is heated by the heat pump 50, and the heated water is returned to the upper part of the tank 10. That is, the tank water circulation passage 20 is a water passage for storing heat in the tank 10. Further, on the upstream side of the heat pump 50 of the tank water circulation passage 20, a thermistor 24 is interposed. The thermistor 24 is derived from the lower part of the tank 10 and measures the temperature of water before passing through the heat pump 50. The thermistor 24 may be provided in the tank water circulation passage 20 at a position closer to the heat pump 50 than the circulation pump 22 or may be provided in the tank water circulation passage 20 at a position near the tank 10 than the circulation pump 22 .

  The upstream end of the tap water introduction passage 30 is connected to the tap water supply source 31. A thermistor 32 is interposed in the tap water introduction passage 30. Thermistor 32 measures the temperature of tap water. The downstream side of the tap water introduction passage 30 is branched into a first introduction passage 30a and a second introduction passage 30b. The downstream end of the first introduction passage 30 a is connected to the lower portion of the tank 10. The downstream end of the second introduction passage 30 b is connected to the middle of the supply passage 40. A mixing valve 42 is provided at the connection between the downstream end of the second introduction passage 30 b and the supply passage 40. The mixing valve 42 adjusts the amount of mixing the water in the second introduction path 30 b with the hot water flowing in the supply path 40.

  The supply path 40 is connected to the upper end of the tank 10 at its upstream end. A combustion device 60 is interposed in the supply passage 40 on the downstream side of the connection with the second introduction passage 30b. Further, a thermistor 44 is interposed in the supply passage 40 downstream of the combustion device 60. The thermistor 44 measures the temperature of the supplied hot water. The combustion device 60 heats the water by the combustion of the fuel gas. The combustion device 60 heats the water in the supply passage 40 so that the temperature of the hot water measured by the thermistor 44 matches the hot water supply set temperature. The downstream end of the supply path 40 is connected to a hot water supply point (for example, a kitchen run, a shower 54 of the bathroom 48, a run 56, etc.). Further, at the downstream end of the supply path 40, a hot water valve 46 for hot watering the bathtub 58 of the bathroom 48 is provided. The hot water filling valve 46 can adjust the flow rate of the hot water supplied to the bathtub 58 by adjusting the opening degree.

  The control unit 70 includes a CPU, a ROM, a RAM, a communication I / F, and the like (not shown). Control unit 70 is electrically connected to each component of water heating apparatus 4 and controls the operation of each component. A remote control 80 is connected to the control unit 70. The remote controller 80 includes a CPU, a ROM, a RAM, a communication I / F, and the like (not shown). Further, the remote controller 80 includes a display unit 80 a that displays various information related to the hot water supply device 4 and an operation unit 80 b that receives various operation inputs related to the hot water supply device 4. The user can set the hot-water supply setting temperature which is the temperature of the water supplied to the shower 54 or the caran 56 etc., the bath setting temperature which is the temperature of the water supplied to the bathtub 58, etc. via the remote control 80. Also, the user can instruct the start of the hot water to the bathtub 58 through the remote control 80.

  As shown in FIG. 1, the remote control 80 can communicate with the router 200 via wireless communication, and can connect to the Internet 250 via the router 200.

  The cooking apparatus 100 is, for example, a cooking apparatus such as a stove, a rice cooker, or a range. The cooking apparatus 100 includes a control unit 102. The control unit 102 can communicate with the remote control 80 via wireless communication. The cooking apparatus 100 transmits a cooking start signal to the remote control 80 when cooking is started (for example, when a burner for cooking is ignited). In addition, the cooking apparatus 100 transmits a cooking completion signal to the remote control 80 when the cooking is finished (for example, when the burner for cooking is extinguished).

  Server device 300 is a server provided by the manufacturer of water heating apparatus 4. The server device 300 includes a control unit 302. The server device 300 is connected to the Internet 250. Therefore, the control unit 302 of the server device 300 can communicate with the remote control 80 of the hot water supply device 4 via the Internet 250. The control unit 302 of the server device 300 can be referred to as a server-side control device. Moreover, the control part 70 and the remote control 80 of the hot-water supply apparatus 4 can be called client side control apparatus.

  Next, the operation of the hot water supply device 4 will be described. The hot water supply device 4 can execute a boiling operation, a hot water supply operation, and a hot water heating operation. In the present specification, both the hot water supply operation and the hot water heating operation of the hot water supply device 4 are referred to as hot water supply by the hot water supply device 4. Each operation will be described below.

(Boiling operation)
The boiling operation is an operation of heating the water in the tank 10 by the heat pump 50. When the execution of the heating operation is instructed by the control unit 70, the heat pump 50 operates and the circulation pump 22 operates. When the circulation pump 22 operates, the water in the tank 10 circulates in the tank water circulation passage 20. That is, when the water present in the lower part of the tank 10 is introduced into the tank water circulation passage 20 and the introduced water passes through the condenser of the heat pump 50, the water heated by the heat of the refrigerant is heated. Is returned to the top of the As a result, high temperature water is stored in the tank 10. Inside the tank 10, a temperature stratification is formed in which a layer of high temperature water is laminated on a layer of low temperature water.

(Hot water supply operation)
The hot water supply operation is an operation for supplying the water in the tank 10 to the hot water supply location. The hot water supply operation can also be performed during the above-described boiling operation. When the hot water supply tap is opened at the hot water supply location, tap water flows into the lower part of the tank 10 from the tap water introduction passage 30 (first introduction passage 30 a) by the water pressure from the tap water supply source 31. At the same time, the hot water in the upper part of the tank 10 is supplied to the hot water supply location through the supply passage 40.

  If the temperature of the water supplied from the tank 10 to the supply passage 40 (ie, the measured temperature of the thermistor 12) is higher than the hot water supply set temperature, the control unit 70 opens the mixing valve 42 to start the second introduction passage 30b. Introduce tap water to the supply passage 40. Therefore, the water supplied from the tank 10 and the tap water supplied from the second introduction passage 30 b are mixed in the supply passage 40. The control unit 70 adjusts the opening degree of the mixing valve 42 so that the temperature of the water supplied to the hot water supply location matches the hot water supply set temperature. On the other hand, when the temperature of the water supplied from the tank 10 to the supply passage 40 is lower than the hot water supply set temperature, the control unit 70 operates the combustion device 60. Accordingly, the water passing through the supply passage 40 is heated by the combustion device 60. The control unit 70 controls the output of the combustion device 60 so that the temperature of the water supplied to the hot water supply location matches the hot water supply set temperature.

(Hot water operation)
In the hot water operation, the water in the tank 10 is supplied to the bathtub 58. When the start of the hot water beam is instructed from the remote controller 80, the control unit 70 opens the hot water valve 46. Thus, the water temperature-controlled to the bath setting temperature is supplied to the bath 58 in the same manner as the hot water supply operation. As described later, the control unit 70 also executes the above-described boiling operation when performing the hot water pouring operation.

(Learning control)
FIG. 3 shows a time zone (shown in the lower part of FIG. 3) in which hot water supply by the hot water supply apparatus 4 is performed during a certain day and a time zone (shown in the upper part of FIG. It is a figure shown typically. In the present embodiment, 24 hours starting at 2:00 is used as a unit time for specifying one day.

  Regarding hot water supply, generally, the first hot water supply is started, for example, from 6:00 to 7:00 (6:00 in the example of FIG. 3). The first hot water supply is, for example, hot water supply for breakfast preparation and washing. In the first hot water supply, approximately 5 L to 20 L of hot water is supplied. Thereafter, for example, the second hot water supply is started at 11:00 to 12:00 (11:00 in the example of FIG. 3). The second hot water supply is, for example, a hot water supply for preparation of lunch. Even in the second hot water supply, about 5 L to 20 L of hot water is supplied. Thereafter, for example, the third hot water supply is started at 20:00 (20:00 in the example of FIG. 3). The third hot water supply is hot water driving to the bathtub 58. In the hot water operation, hot water of about 150 liters to 180 liters is supplied. Thereafter, for example, the last hot water supply is started from 23:00 to 0:00 (approximately 23:00 in the example of FIG. 3). The last hot water supply is, for example, hot water supply for brushing teeth and the like. In the last hot water supply, approximately 5 liters to 10 liters of hot water is supplied. The last hot water supply ends at around 0:00.

  Moreover, regarding cooking, cooking C1 of breakfast is generally started, for example, from 6:00 to 7:00 (7:00 in the example of FIG. 3). The cooking C1 of breakfast ends in, for example, 30 minutes. Thereafter, for example, cooking C2 for lunch is started at 11:00 to 12:00 (12:00 in the example of FIG. 3). Lunch preparation C2 ends in, for example, 30 minutes. Thereafter, for example, dinner cooking C3 is started from 17:00 to 18:00 (18:00 in the example of FIG. 3). The dinner cooking C3 ends in, for example, 30 minutes. In addition to cooking C1, C2 and C3 of these meals, for example, cooking C4 of boiling water in a kettle for drinking tea is performed during the time between lunch and dinner (15:00 in the example of FIG. 3) Sometimes. Such cooking C4 is completed in, for example, 5 minutes. In addition, after the family returning home is late (21:00 in the example of FIG. 3), cooking C5 for dinner for the family may be performed. Such cooking C5 is completed in, for example, 30 minutes.

  In the present embodiment, every time the hot water supply is performed in the hot water supply apparatus 4, the control unit 70 indicates the time when the hot water supply was started, the time when the hot water supply ended, and the hot water use amount indicating the amount of hot water used for hot water supply. , As the hot water supply record. Further, every time the control unit 70 receives the cooking start signal and the cooking end signal from the cooking apparatus 100 via the remote control 80, the control unit 70 stores the time when the cooking is started and the time when the cooking is finished as the cooking result. Then, the control unit 70 transmits the hot water supply result for one day and the cooking result for the one day to the control unit 302 of the server device 300 as the operation history for one day. The control part 302 of the server apparatus 300 has memorize | stored the driving | operation log | history of the hot-water supply apparatus 4 and the cooking apparatus 100 in each day of the past predetermined period (for example, seven days).

  Then, the process which the hot-water supply system 2 performs every 24 hours (every time becomes 2:00) is demonstrated. The control unit 70 of the hot water supply device 4 transmits the operation history of the previous day to the control unit 302 of the server device 300 together with the current detection temperature of the thermistor 32 every 24 hours. Control unit 302 newly stores the operation history of water heating apparatus 4 and cooking apparatus 100 on the previous day.

  Next, the control unit 302 identifies, from the operation history for the past seven days, the earliest time of the times (first hot water supply start time) at which the first hot water supply was started in the past seven days. Hereinafter, this time is referred to as "hot water supply start time S1". For example, the control unit 302 specifies 6:00 as the hot water supply start time S1 (see FIG. 3).

  Furthermore, the control unit 302 specifies the largest amount of hot water usage among the amounts of hot water usage from the hot water supply start time to the hot water start before the hot water start from the operation history for the past seven days in the past seven days. Below, this hot-water supply usage amount is called "1st hot-water supply amount Q1." For example, the control unit 302 specifies 30L as the first hot water supply amount Q1.

  Further, the control unit 302 specifies the earliest time of the times (hot water start time) at which the hot water has been started in the past seven days from the operation history for the past seven days. Hereinafter, this time is referred to as "hot-spring start time B1". For example, the control unit 302 specifies 20:00 as the hot water start time B1 (see FIG. 3).

  Furthermore, the control unit 302 specifies the latest time of the times (the hot water supply end time) at which the last hot water supply has ended in the past seven days from the operation history for the past seven days. Hereinafter, this time is referred to as “hot water supply end time G1”. For example, the control unit 302 specifies 0:00 as the hot water supply end time G1 (see FIG. 3).

  Furthermore, the control unit 302 specifies the first predetermined time α based on the detected temperature TW of the thermistor 32 (that is, the water temperature TW of the tap water) and the first hot-water supply amount Q1. In addition, the control unit 70 specifies the second predetermined time β and the third predetermined time γ based on the water temperature TW of the tap water.

  For example, when the water temperature TW of tap water is 21 ° C. or higher, the control unit 302 specifies “20 minutes” as the first predetermined time α. When the water temperature TW is 13 ° C. or more and less than 21 ° C., the control unit 302 specifies “30 minutes” as the first predetermined time α. When the water temperature TW is less than 13 ° C., the control unit 302 specifies “45 minutes” as the first predetermined time α. Control part 302 specifies short time as the 1st predetermined time alpha, so that water temperature TW of tap water is high. Also, for example, when the first hot-water supply amount Q1 is less than 12 L, the control unit 302 specifies “5 minutes” as the addition time of the first predetermined time α. When the first hot-water supply amount Q1 is 12L or more and less than 30L, the control unit 302 specifies “10 minutes” as the addition time of the first predetermined time α. When the first hot water supply amount Q1 is 30 L or more, the control unit 302 specifies “15 minutes” as the addition time of the first predetermined time α. The control unit 302 specifies a short time as the addition time of the first predetermined time α as the first hot-water supply amount Q1 is smaller.

  Similarly, for example, when the water temperature TW of tap water is 21 ° C. or more, the control unit 302 specifies “40 minutes” as the second predetermined time β. When the water temperature TW is 13 ° C. or more and less than 21 ° C., the control unit 302 specifies “50 minutes” as the second predetermined time β. If the water temperature TW is less than 13 ° C., the control unit 302 specifies “60 minutes” as the second predetermined time β. Control part 302 specifies a short time as the 2nd predetermined time beta, so that water temperature TW of tap water is high.

  Furthermore, for example, when the water temperature TW of tap water is 21 ° C. or more, the control unit 302 specifies “80 minutes” as the third predetermined time γ. When the water temperature TW is 13 ° C. or more and less than 21 ° C., the control unit 302 specifies “50 minutes” as the third predetermined time γ. If the water temperature TW is less than 13 ° C., the control unit 302 specifies “40 minutes” as the third predetermined time γ. The control unit 302 specifies a longer time as the third predetermined time γ as the water temperature TW of the tap water is higher.

  Next, the control unit 302 specifies a first heat pump operation time S0 that is a time before the specified first predetermined time α from the hot water supply start time S1. Further, the control unit 302 specifies a second heat pump operation time B0 which is a time that is earlier than the specified second predetermined time β from the hot water start time B1. Furthermore, the control unit 302 specifies the heat pump stop time G0 that is the time before the specified third predetermined time γ from the hot water supply end time G1.

  In addition, the control unit 302 specifies the earliest time of the times (supper cooking start time) at which the cooking of the dinner has started in the past seven days from the operation history for the past seven days. Hereinafter, this time is referred to as "supper cooking start time D1". For example, the control unit 302 specifies 18:00 as the supper cooking start time D1 (see FIG. 3). In addition, the control part 302 specifies the time when cooking of dinner was started from the cooking results for one day as shown in FIG. 3 as follows.

  First, when the elapsed time from the start time of cooking to the finish time of the cooking does not reach a predetermined time (for example, 10 minutes), the control unit 302 determines that the cooking is not dinner cooking. By this, it is judged that cooking C4 shown in FIG. 3 is not cooking of dinner. In addition, when the start time of the cooking is before the predetermined time (for example, 14:00), the control unit 302 determines that the cooking is not the cooking of the dinner. By this, it is judged that cooking C1 and C2 shown in FIG. 3 are not cooking of dinner. Furthermore, when the start time of the cooking is later than the hot water start time of the day, the control unit 302 determines that the cooking is not the cooking of the dinner. By this, it is judged that cooking C5 shown in FIG. 3 is not cooking of dinner. Although the cooking C5 shown in FIG. 3 actually corresponds to the cooking of dinner, in the present embodiment, only the cooking of dinner performed before the start of hot water pouring is considered, so the control unit 302 Such cooking C5 is treated as not being prepared for dinner. As described above, the control unit 302 extracts the cooking C3 for dinner from the cooking results for one day as shown in FIG. 3 and specifies the time when the cooking starts as the dinner cooking start time.

  The control unit 302 determines the hot water supply start time S1, the first hot water supply amount Q1, the hot water start time B1, the hot water supply end time G1, the first heat pump activation time S0, and the second heat pump activation time specified as described above. B0, the heat pump stop time G0, and the supper cooking start time D1 are transmitted to the control unit 70. The control unit 70 receives the hot water supply start time S1 received from the control unit 302, the first hot water supply amount Q1, the hot water start time B1, the hot water supply completion time G1, the first heat pump activation time S0, the second heat pump activation time B0, the heat pump The stop time G0 and the dinner cooking start time D1 are stored.

(First heat pump operation process)
Thereafter, when the first heat pump operation time S0 arrives, the control unit 70 starts the process of FIG. 4. FIG. 4 is a flowchart showing the contents of the first heat pump operation process executed by the control unit 70.

  First, in S10, the control unit 70 selects a thermistor corresponding to the first hot water supply amount Q1 among the thermistors 12, 14, 16, 17, 18 attached to the tank 10. In the present embodiment, since the first hot water supply amount Q1 is 30L, the control unit 70 selects the thermistor 16 corresponding to 30L.

  At S12, the control unit 70 determines whether the temperature measured by the thermistor 16 selected at S10 (that is, the water temperature 30 L from the top of the tank 10) is higher than a predetermined threshold value TA.

  In the present embodiment, the predetermined threshold value TA is “boiling set temperature −10 ° C.”. The boiling set temperature is, for example, 47 ° C. Therefore, the predetermined threshold value TA is, for example, 37.degree. If it is determined YES in S12, the water temperature at the position of 30 L from the top of the tank 10 is at least higher than the threshold value TA (for example, 37 ° C.). As described above, inside the tank 10, a temperature stratification is formed in which a layer of high temperature water is laminated on a layer of low temperature water. Therefore, when it is determined YES in S12, high temperature water close to the boiling set temperature (for example, 47 ° C.) is stored between the position of 30 L of the tank 10 and the upper portion of the tank. That is, when it is judged YES in S12, hot water of an amount (about 5 L to 20 L) necessary for the first hot water supply scheduled to be performed near the hot water supply start time S1 is stored in the tank 10. It means that. When it is judged as YES by S12, it progresses to S18. On the other hand, when it is judged as NO by S12, it progresses to S14.

  At S14, the control unit 70 determines whether the heat pump 50 is operating. When the heat pump 50 is operating, the control unit 70 determines YES in S14, and returns to S12. In this case, the control unit 70 continues the heating operation of heating the water in the tank 10 by the heat pump 50. On the other hand, when the heat pump 50 is not operating, the control unit 70 determines NO in S14, and proceeds to S16.

  At S16, the control unit 70 operates the heat pump 50. Further, the control unit 70 rotates the circulation pump 22. That is, the control unit 70 starts the boiling operation. Thereby, the water present in the lower part of the tank 10 is introduced into the tank water circulation passage 20, the introduced water is heated by the heat pump 50, and the heated water is returned to the upper part of the tank 10. As a result, high temperature water is stored in the tank 10. After activating the heat pump 50 in S16, the process returns to S12, and the control unit 70 determines that the temperature measured by the thermistor 16 is higher than a predetermined threshold value TA (that is, the water of the first hot water supply amount Q1 is predetermined in the tank 10). Monitoring that the water temperature is higher than the threshold value TA of If the temperature measured by the thermistor 16 becomes higher than the predetermined threshold value TA (YES in S12), the process proceeds to S18.

  In S18, the control unit 70 stops the heat pump 50 and the circulation pump 22. As described above, when it is determined YES in S12, warm water of an amount (the first hot-water supply amount Q1 (30 L)) necessary for the first hot-water supply is already stored in the tank 10.

  When the first hot water supply operation is performed at a time near the hot water supply start time S1 after the first heat pump activation process of FIG. 4 is started, the hot water in the upper part of the tank 10 is supplied to the hot water supply location via the supply passage 40 Supplied. As described above, in the hot water supply system 2 of the present embodiment, it is possible to store the amount of hot water necessary for hot water supply in the tank 10 at the hot water supply start time S1. That is, by operating the heat pump 50 only for the first predetermined time α, it is possible to store an amount of hot water necessary for hot water supply in the tank 10 at the hot water supply start time S1. It's time.

(Correction process of second heat pump operation time B0)
After the first heat pump activation process, the control unit 70 monitors that the cooking of the dinner is started in the cooking apparatus 100 until the dinner cooking start time D1 is reached. Specifically, when the control unit 70 receives the cooking start signal from the cooking apparatus 100, if the current time is before the predetermined time (for example, 14:00), the cooking performed by the cooking apparatus 100 is I judge that it is not cooking for dinner. In addition, when the control unit 70 receives the cooking start signal from the cooking apparatus 100, before the predetermined time (for example, 10 minutes) elapses, even if the current time is after the predetermined time (for example, 14:00) When the cooking completion signal is received from the cooking apparatus 100, it is determined that the cooking is not the cooking of the dinner. When the control unit 70 receives the cooking start signal from the cooking apparatus 100, the current time is later than the predetermined time (for example, 14:00), and the cooking apparatus 100 receives the predetermined time (for example, 10 minutes). When the cooking completion signal is not received, it is determined that the cooking of the dinner is started in the cooking apparatus 100.

  The control unit 70 starts the supper cooking with the cooking apparatus 100 before the supper cooking start time D1 arrives, that is, when the start of the supper cooking on the day is earlier than the supper cooking start time D1. Since the start of the hot water beam on the day may be earlier than the hot water start time B1, the second heat pump operation time B0 is advanced. For example, the control unit 70 calculates a time difference ΔT from the time when cooking of dinner is started in the cooking apparatus 100 to the dinner cooking start time D1, and advances the second heat pump operation time B0 by the time difference ΔT. By this, even when the start of the hot water beam on the day is earlier than the hot water start time B1, it is possible to store in the tank 10 the warm water necessary before the start of the hot water beam.

  In the present embodiment, when the cooking of the dinner is started by the cooking apparatus 100 after the dinner cooking start time D1 comes, the control unit 70 starts the dinner cooking of the day, that is, the dinner cooking start time D1. If it is later, the second heat pump operation time B0 is not changed. Even if the start of the dinner preparation on the day is later than the dinner preparation start time D1, the start of the hot water on the day may not change from the hot water start time B1. By comprising as mentioned above, warm water can be reliably stored in the tank 10 at the time of the start of a water heating. Unlike this, when the supper cooking is started by the cooking apparatus 100 after the supper cooking start time D1 comes, ie, the supper cooking start on the day is later than the supper cooking start time D1 Alternatively, the second heat pump operation time B0 may also be delayed.

(Second heat pump operation process)
Thereafter, when the second heat pump operation time B0 comes, the control unit 70 starts the process of FIG. 5. FIG. 5 is a flowchart showing the contents of the second heat pump operation process executed by the control unit 70.

  First, in S30, the control unit 70 determines whether the temperature measured by the thermistor 24 (that is, the temperature of water derived from the lower part of the tank 10 and before passing through the heat pump 50) is higher than a predetermined threshold TB ( That is, it is determined whether or not the tank 10 is fully stored. When it is judged as YES by S30, it progresses to S38. On the other hand, when it is judged as NO by S30, it progresses to S32.

  At S32, the control unit 70 operates the heat pump 50. Further, the control unit 70 rotates the circulation pump 22. That is, the control unit 70 starts the boiling operation. In addition, when the heat pump 50 and the circulation pump 22 are already operating at the time of S32, the control part 70 operates the heat pump 50 and the circulation pump 22 continuously. When S32 ends, the process proceeds to S34.

  On the other hand, in S38, the heat pump 50 and the circulation pump 22 are stopped. As described above, when it is determined YES in S30, the tank 10 is in the full storage state. Therefore, it is not necessary to operate the heat pump 50 and the circulation pump 22 any more. When S38 ends, the process proceeds to S34.

  At S34, control unit 70 determines whether or not a hot water pouring start instruction has been issued from remote control 80. When it is judged as YES by S34, it progresses to S36 and starts a hot water pouring process (refer FIG. 5). On the other hand, if NO in S34, the process returns to S30.

  In the present embodiment, the control unit 70 operates the heat pump 50 at the second heat pump activation time B0 (S32), and the temperature measured by the thermistor 24 becomes lower than the predetermined threshold TB at the hot water start time B1. Thus, the second predetermined time β is specified. However, the time when the user actually instructs the start of the water bath may be earlier or later than the water bath start time B1. In addition, the amount of hot water in the tank 10 at the second heat pump activation time B0 may be larger or smaller than expected. For this reason, after activating the heat pump 50 in the above-described S32, the user may be instructed by the user to start the hot-water pouring before the tank 10 becomes full-stocked, or the tank 10 becomes fully-stocked After stopping the heat pump 50 in S38 described above, the user may issue an instruction to start the water bath.

(Hot water treatment)
As described above, when the user instructs to start the hot water beam, in S36, the control unit 70 starts the hot water heating process. FIG. 6 is a flowchart showing the contents of the hot water treatment.

  At S50, control unit 70 starts the hot water pouring operation. That is, the control unit 70 opens the hot water release valve 46 provided in the supply path 40 to the bathtub 58 and starts the supply of the hot water to the bathtub 58.

  In S52, the control unit 70 determines whether the heat pump 50 is operating. When the heat pump 50 is operating, the control unit 70 determines YES in S52, and proceeds to S58. On the other hand, when the heat pump 50 is stopped, the control unit 70 determines NO in S52, and proceeds to S54.

  In S54, the control unit 70 monitors that the temperature measured by the thermistor 18 becomes equal to or less than a predetermined threshold value TA. In S54, instead of monitoring the temperature measured by the thermistor 18, it may be monitored that the temperature measured by the thermistor 24 becomes equal to or less than a predetermined threshold value TA. In the case of YES in S54, the process proceeds to S56. In S56, the control unit 70 operates the heat pump 50 and rotates the circulation pump 22.

  In S58, the control unit 70 controls the operation and stop of the combustion device 60. For example, the control unit 70 operates the combustion device 60 when the temperature measured by the thermistor 12 (that is, the water temperature 6 L from the top of the tank 10) becomes equal to or lower than the bath setting temperature. In this case, the hot water heated by the heat pump 50 and the combustion device 60 is supplied to the bath 58. In addition, the control unit 70 stops the combustion device 60 when the temperature measured by the thermistor 14 (that is, the water temperature 12 L from the top of the tank 10) exceeds the bath setting temperature. In this case, the hot water heated by the heat pump 50 is supplied to the bath 58.

  At S60, the control unit 70 monitors completion of the water heating operation. When the amount L (for example, 150 L) of water to be supplied to the bathtub 58 in the hot water heating operation is finished supplied to the bathtub 58, the control unit 70 determines YES in S60, and proceeds to S62. If NO in S60, the process returns to S52.

  In S62, the control unit 70 stands by until the temperature measured by the thermistor 24 becomes higher than a predetermined threshold value TB (ie, until the tank 10 is fully stored). If it is determined YES in S62, the heat pump 50 is stopped in S64. When S64 is finished, the hot water heating process of FIG. 6 ends. At the same time, the processing of FIG.

  As described above, in the hot water system 2 of the present embodiment, at the hot water start time B1, it is possible to store a part of the hot water of the amount necessary for the hot water filling in the tank 10. That is, by operating the heat pump 50 only for the second predetermined time β, it is possible to store the necessary amount of hot water in the tank 10 at the hot water start time B1. It is.

(Heat pump stop processing)
Thereafter, when the heat pump stop time G0 comes, the control unit 70 starts the heat pump stop process (not shown). That is, the control unit 70 stops the heat pump 50 when the heat pump 50 is operating at the time of the heat pump stop time G0. When the heat pump 50 is not operating, the control unit 70 stops the heat pump 50 as it is. When the heat pump 50 is stopped at the heat pump stop time G0, the control unit 70 does not operate the heat pump 50 until the next day. Thereafter, at the time near the hot water supply end time G1, the last hot water supply operation ends. Therefore, in the hot water supply system 2 of the present embodiment, it is possible to prevent excessive hot water from being stored in the tank 10 at the hot water supply completion time G1. That is, by not operating the heat pump 50 during the third predetermined time γ, it is possible to prevent excessive hot water from being stored in the tank 10 at the time of the hot water supply completion time G1. It's time.

  In the above embodiment, the control unit 70 may specify the average time of the supper cooking start time in the past seven days as the supper cooking start time D1 from the operation history for the past seven days. Moreover, the control part 70 may specify the average time of the hot water start time in the past 7 days as hot water start time B1 from the driving history for the past 7 days.

  Alternatively, the control unit 70 may specify the second earliest time of the supper cooking start time in the past seven days as the supper cooking start time D1 from the driving history for the past seven days. Further, the control unit 70 may specify, from the operation history for the past seven days, the second earliest time among the hot water start times in the past seven days as the hot water start time B1. With such a configuration, even if there is a day on which dinner cooking or hot water was performed extremely early in the past in a specific period, the operation history of that day is excluded from the target of learning control. Thus, it is possible to improve the estimation accuracy of the hot water start time B1 and the supper cooking start time D1.

  The hot water supply system 2 of the present embodiment includes a tank 10 for storing water, a heat pump 50 (an example of a heat source unit) for boiling water in the tank 10, and a supply path 40 (hot water path for supplying water from the tank 10 to the tub 58). And a control unit capable of communicating with the cooking apparatus 100, and a control unit 302 (an example of a control device). The control unit 70 and the control unit 302 are configured to have a hot water start time at which water supply to the bathtub 58 is started for each day in a predetermined period in the past (for example, seven days), and Based on the supper cooking start time which is the time when cooking was started, it is comprised so that the hot water start time B1 and the supper cooking start time D1 of the day may be estimated. The control unit 70 and the control unit 302 set the second heat pump operation time B0 (an example of the boiling start time) of the current day based on the estimated hot water start time B1 of the current day, and set second When the heat pump operation time B0 comes, the heat pump 50 is configured to execute water boiling of the tank 10. The control unit 70 and the control unit 302 are configured to set the second heat pump operation time when the cooking of the dinner by the cooking apparatus 100 is started on the day before the estimated dinner cooking start time D1 of the day comes. It is configured to advance B0.

  In the hot water supply system 2 of the present embodiment, the control unit 70 and the control unit 302 are set when the cooking of the dinner by the cooking apparatus 100 is started on the day after the estimated dinner cooking start time D1 of the day comes. It is configured not to change the second heat pump operation time B0.

(Example 2)
The hot water supply system 202 of the present embodiment has the same configuration as the hot water supply system 2 of the first embodiment shown in FIG. 1, but the contents of the process performed by the control unit 302 in learning control and the control unit 70 execute The contents of the correction process of heat pump operation time B0 of 2 are different.

(Learning control)
In the hot water supply system 202 of the present embodiment, instead of specifying the supper cooking start time D1, the control unit 302 sets the time difference from the start of the supper cooking to the start of the hot water heating “supper cooking and hot water time difference ΔD1”. Identify as Specifically, the control unit 302 calculates the time difference from the dinner cooking start time to the hot water start time for the past seven days from the driving history for the past seven days, and the longest time difference in the past seven days is It is specified as dinner cooking and hot water baking time difference ΔD1. For example, the control unit 302 specifies 2 hours as the supper cooking / hot water baking time difference ΔD1 (see FIG. 3).

(Correction process of second heat pump operation time B0)
In the present embodiment, after the end of the first heat pump activation process (see FIG. 4), the control unit 70 monitors that the cooking of the supper is started in the cooking apparatus 100 until the second heat pump activation time B0 is reached. Do. Specifically, when the control unit 70 receives the cooking start signal from the cooking apparatus 100, if the current time is before the predetermined time (for example, 14:00), the cooking performed by the cooking apparatus 100 is I judge that it is not cooking for dinner. In addition, when the control unit 70 receives the cooking start signal from the cooking apparatus 100, before the predetermined time (for example, 10 minutes) elapses, even if the current time is after the predetermined time (for example, 14:00) When the cooking completion signal is received from the cooking apparatus 100, it is determined that the cooking is not the cooking of the dinner. When the control unit 70 receives the cooking start signal from the cooking apparatus 100, the current time is later than the predetermined time (for example, 14:00), and the cooking apparatus 100 receives the predetermined time (for example, 10 minutes). When the cooking completion signal is not received, it is determined that the cooking of the dinner is started in the cooking apparatus 100.

  The control unit 70 calculates a time difference ΔD1 ′ from the time when cooking of dinner is started by the cooking apparatus 100 to the hot water filling start time B1, and the calculated time difference ΔD1 ′ is larger than the dinner cooking / hot water baking time difference ΔD1. , The second heat pump operation time B0 is advanced. For example, the control unit 70 calculates a difference ΔT between the calculated time difference ΔD1 'and the dinner cooking / hot water baking time difference ΔD1, and advances the second heat pump operation time B0 by ΔT. By this, even when the start of the hot water beam on the day is earlier than the hot water start time B1, it is possible to store in the tank 10 the warm water necessary before the start of the hot water beam.

  In the present embodiment, when the time difference ΔD1 ′ from the time when the cooking of the supper is started by the cooking apparatus 100 to the start time B1 of the hot water pouring is smaller than the cooking time difference ΔD1 of the cooking and cooking, the control unit 70 The second heat pump operation time B0 is not changed. In this case, although it is considered that the start of the preparation of dinner on the day is delayed, the start of the hot water on the day may not change from the hot water start time B1. By configuring as described above, even in such a case, it is possible to reliably store the hot water in the tank 10 at the start of the water heating. In addition, different from this, when the time difference ΔD1 ′ from the time when the cooking of the supper is started by the cooking apparatus 100 to the hot water start time B1 is smaller than the supper cooking · hot water time difference ΔD1, the second heat pump operation is performed. The time B0 may be delayed.

  In the above, from the operation history for the past 7 days, the control unit 70 calculates the time difference from the supper cooking start time to the hot water start time for the past 7 days, and averages the time differences in the past 7 days It may be specified as the cooking / hot-water-heating time difference ΔD1.

  Alternatively, from the operation history for the past seven days, the control unit 70 specifies the second longest time difference among the time differences from the supper cooking start time to the hot water start time in the past seven days as the supper cooking / hot water time difference ΔD1. You may With such a configuration, even if there is a day when the time difference from cooking of the supper to the bathing becomes extremely long specifically in the past predetermined period, the operation history of that day is excluded from the subject of learning control By doing this, it is possible to improve the estimation accuracy of the supper cooking / hot water baking time difference ΔD1.

  The hot water supply system 92 of the present embodiment includes a tank 10 for storing water, a heat pump 50 (an example of a heat source machine) for boiling water in the tank 10, and a supply path 40 (hot water path for supplying water from the tank 10 to the tub 58). And a control unit capable of communicating with the cooking apparatus 100, and a control unit 302 (an example of a control device). The control unit 70 and the control unit 302 are configured to have a hot water start time at which water supply to the bathtub 58 is started for each day in a predetermined period in the past (for example, seven days), and Based on the difference between the time until the water supply to the bathtub 58 is started after the cooking is started, the hot water start time B1 of the day and the hot water cooking time difference ΔD1 are estimated on the basis of the hot water start time difference on the day Is configured as. The control unit 70 and the control unit 302 set the second heat pump operation time B0 (an example of the boiling start time) of the current day based on the estimated hot water start time B1 of the current day, and set second When the heat pump operation time B0 comes, the heat pump 50 is configured to execute water boiling of the tank 10. The control unit 70, the control unit 302, the time difference from the time when the cooking of the dinner was started by the cooking apparatus 100 on the day to the estimated hot water start time B1 of the day is the estimated dinner cooking / hot water time difference on the day When it is larger than ΔD1, the set second heat pump operation time B0 is advanced.

  In the hot water supply system 2 of the present embodiment, the control unit 70 and the control unit 302 have the time difference from the time when the cooking of the dinner was started by the cooking apparatus 100 on the day to the hot water start time B1 estimated on the day When it is smaller than the estimated dinner cooking and hot water baking time difference ΔD1, the set second heat pump operation time B0 is not changed.

  In the hot water supply systems 2 and 92 of the first and second embodiments, when the control unit 70 and the control unit 302 start cooking by the cooking apparatus 100 and before the predetermined time (for example, 10 minutes) elapses, the cooking is completed. It is configured to judge that the cooking is not dinner cooking.

  In the hot water supply systems 2 and 92 of the first and second embodiments, the control unit 70 and the control unit 302 are configured to prepare dinner when cooking is started by the cooking apparatus 100 before a predetermined time (for example, 14:00). It is configured to judge that it is not cooking.

  In the hot water supply systems 2 and 92 of the first and second embodiments, the control unit 70 and the control unit 302 cause the cooking apparatus 100 to start cooking when cooking is started by the cooking apparatus 100 after the start of the supply of water to the bathtub 58. It is configured to judge that it is not cooking.

  In the water heating systems 2 and 92 of the first and second embodiments, the control unit 302 of the server device 300 corresponds to a server-side control device, and the control unit 70 corresponds to a client-side control device capable of communicating with the control unit 302.

  In the hot water supply systems 2 and 92 of the first and second embodiments, a part or all of the process performed by the control unit 302 of the server device 300 is compared to the control unit 70 of the hot water supply device 4, the remote control 80, and the cooking device The configuration may be performed by the control unit 102 of For example, among processes related to learning control performed by the control unit 302 of the server device 300, the hot water supply start time S1, the first hot water supply amount Q1, the hot water start time B1, the hot water supply end time G1, the first heat pump activation time S0, The process regarding the specification of the second heat pump activation time B0 and the heat pump stop time G0 is performed by the control unit 70 of the hot water supply apparatus 4, and the process regarding the specification of the dinner cooking start time D1 or the dinner cooking / hot water baking time difference ΔD1 is the server device 300 The control unit 302 may perform this.

  In the hot water supply systems 2 and 92 of the first and second embodiments, the remote control 80, the control unit 102 of the cooking apparatus 100, and the control unit 302 of the server apparatus 300 perform part or all of the processing performed by the control unit 70. It is good also as composition.

  In the hot water supply systems 2 and 92 of the first and second embodiments, the heat pump 50 is used as a heat source machine for boiling water in the tank 10. However, other heat source machines such as burners, electric heaters, cogeneration systems, etc. The water of the tank 10 may be boiled using another heat source machine.

  Although the embodiments of the present invention have been described above in detail, these are merely examples and do not limit the scope of the claims. The art set forth in the claims includes various variations and modifications of the specific examples illustrated above.

  The technical elements described in the present specification or the drawings exhibit technical usefulness singly or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques exemplified in the present specification or the drawings can simultaneously achieve a plurality of purposes, and achieving one of the purposes itself has technical utility.

2: hot water supply system 4: hot water supply system 10: tank 12: thermistor 14: thermistor 16: thermistor 17: thermistor 18: thermistor 20: tank water circulation passage 22: circulation water pump 24: thermistor 30: tap water introduction passage 30a: first introduction passage 30b: second introduction passage 31: tap water supply source 32: thermistor 40: supply passage 42: mixing valve 44: thermistor 46: hot water valve 48: bathroom 50: heat pump 54: shower 56: currant 58: bathtub 60: combustion device 70: control unit 80: remote control 80a: display unit 80b: operation unit 92: hot water supply system 100: cooking apparatus 102: control unit 200: router 202: hot water supply system 250: Internet 300: server device 302: control unit

Claims (8)

A tank for storing water,
A heat source machine for boiling water in the tank,
The hot water route that supplies water from the tank to the bathtub,
It has a controller that can communicate with the cooking device,
The control device sets a hot water start time, which is a time when supply of water to the bathtub is started, and a supper cooking start time, which is a time when dinner cooking is started by the cooking apparatus, for each day in a predetermined period in the past Based on, it is configured to estimate the start time of the hot water of the day and the start time of dinner cooking,
The control device sets the boiling start time of the day based on the estimated hot water start time of the day, and executes the boiling of the water of the tank by the heat source machine when the set boiling start time comes Is configured as
The control device is configured to advance the set boiling start time when the cooking of the dinner is started by the cooking device on the day before the estimated dinner cooking start time of the day comes. Hot water supply system.   The control device is configured not to change the set boiling start time when the cooking of the dinner is started by the cooking device on the day after the estimated dinner cooking start time of the day has come. The hot water supply system according to claim 1. A tank for storing water,
A heat source machine for boiling water in the tank,
The hot water route that supplies water from the tank to the bathtub,
It has a controller that can communicate with the cooking device,
The control device is configured to supply the water to the bathtub after the start of the supper cooking by the cooking apparatus and the hot water start time that is the time at which the supply of water to the bathtub was started for each day in the past predetermined period. It is configured to estimate the hot water start time of the day and the dinner cooking and hot water baking time difference based on the dinner cooking and hot water baking time difference that is the time difference until the start of the
The control device sets the boiling start time of the day based on the estimated hot water start time of the day, and executes the boiling of the water of the tank by the heat source machine when the set boiling start time comes Is configured as
The control device is set when the time difference from the time when the cooking of the dinner was started by the cooking device on the day to the estimated start time of the hot water on the day is larger than the estimated dinner time on the current day The hot water supply system, which is configured to advance the boiling start time.   The control device is set when the time difference from the time when the cooking of the dinner was started by the cooking device on the day to the estimated start time of the hot water on the day is smaller than the estimated dinner time on the current day The hot water supply system according to claim 3, wherein the hot water supply system according to claim 3, wherein the hot water supply start time is not changed.   The control device is configured to determine that the cooking is not a dinner cooking if the cooking is finished before a predetermined time has elapsed since the cooking was started by the cooking device. The hot water supply system of any one of 4.   The hot water supply system according to any one of claims 1 to 5, wherein the control device is configured to determine that the cooking is not cooking for dinner when the cooking device starts cooking before the predetermined time. system.   The control device is configured to determine that cooking is not cooking for dinner when cooking is started by the cooking device after the start of the supply of water to the bathtub. Or a hot water supply system.   The hot water supply system according to any one of claims 1 to 7, wherein the control device includes a server side control device and a client side control device capable of communicating with the server side control device.

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